Base station, terminal, and wireless communication system

ABSTRACT

A base station includes a licensed band transmitting unit, a determining unit, and an unlicensed band transmitting unit. The licensed band transmitting unit transmits, to a terminal, a control signal for specifying a resource in a shared band to be used for data transmission by the terminal. The determining unit determines whether the resource in the shared band is idle or busy. The unlicensed band transmitting unit transmits a permission signal for permitting transmission in the shared band when the determining unit determines that the resource in the shared band is idle. The control signal or the permission signal includes an offset indicating a time from the permission signal to a start of transmission of data from the terminal to the base station with reference to the permission signal transmitted from the unlicensed band transmitting unit.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a continuation of U.S. application Ser. No.15/703,606, filed on Sep. 13, 2017, now pending, which is a continuationapplication of International Application PCT/JP2015/060770, filed onApr. 6, 2015, and designating the U.S., the entire contents of each areincorporated herein by reference.

FIELD

The present invention relates to a base station, a terminal, and awireless communication system.

BACKGROUND

In recent years, in order to achieve a higher speed and a largercapacity in wireless communications performed in wireless communicationsystems such as a mobile telephone system, some discussions aboutnext-generation wireless communication technologies have been made. Forexample, a technology has been discussed about establishing acommunication using a carrier in a frequency band that requires alicense (licensed band carrier (LC)) and a carrier in a frequency bandthat does not require a license (unlicensed band carrier (UC)) in acommunication standard referred to as long term evolution (LTE). Thistechnology is referred to as licensed assisted access (LAA).

In the LAA, when a terminal performs an up Link (UL) transmission to abase station in an unlicensed band, the base station transmits a ULgrant, which requests transmission of data, to the terminal via alicensed band. Further, for example, the base station performs listenbefore talk (LBT) in the unlicensed band before the terminal performsthe UL transmission. Furthermore, for example, there have beendiscussions to cause the base station, upon detecting that theunlicensed band is idle, to transmit a reservation signal in theunlicensed band until a timing of the UL transmission performed by theterminal, in order to reserve the unlicensed band used by the terminalfor the UL transmission. This allows the terminal to perform the ULtransmission by using the unlicensed band a predetermined time after theUL grant. Prior art example is disclosed in 3GPP RAN1 Contributiondocument R1-150186.

Incidentally, in the technology disclosed in the above-referenced NonPatent Literature, if a busy state of the unlicensed band is continuedand the terminal does not receive the reservation signal in theunlicensed band until the timing of the UL transmission, the terminalcancels the UL transmission, for example. Accordingly, the opportunityof transmitting data scheduled to be transmitted by the UL transmissionis suspended until a predetermined period elapses after a next UL granttransmitted from the base station. Therefore, in some cases, athroughput of data transmission in an uplink from the terminal to thebase station may be reduced.

SUMMARY

A base station disclosed, according to an aspect, performs wirelesscommunication with a terminal by using a dedicated band dedicated to awireless communication system including the base station and theterminal and a shared band shared with other systems. The base stationincludes a control signal transmitting unit, a determining unit, apermission signal transmitting unit. The control signal transmittingunit transmits, to the terminal, a control signal for specifying aresource in the shared band to be used for data transmission by theterminal. The determining unit determines whether the resource in theshared band is idle or busy. The permission signal transmitting unittransmits a permission signal for permitting transmission in the sharedband when the determining unit determines that the resource in theshared band is idle. The control signal or the permission signalincludes an offset indicating a time from the permission signal to astart of transmission of data from the terminal to the base station withreference to the permission signal transmitted from the permissionsignal transmitting unit.

The object and advantages of the invention will be realized and attainedby means of the elements and combinations particularly pointed out inthe claims.

It is to be understood that both the foregoing general description andthe following detailed description are exemplary and explanatory and arenot restrictive of the invention.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a schematic diagram illustrating an example of a wirelesscommunication system.

FIG. 2 is a schematic diagram illustrating an example of operation ofthe wireless communication system in the first embodiment.

FIG. 3 is a schematic diagram illustrating an example of operation ofthe wireless communication system in the first embodiment.

FIG. 4 is a block diagram illustrating an example of the base station.

FIG. 5 is a block diagram illustrating an example of the terminal.

FIG. 6 is a flowchart illustrating an example of operation of the basestation.

FIG. 7 is a flowchart illustrating an example of operation of the basestation.

FIG. 8 is a flowchart illustrating an example of operation of theterminal.

FIG. 9 is a schematic diagram illustrating an example of operation of awireless communication system in a third embodiment.

FIG. 10 is a schematic diagram illustrating an example of operation of awireless communication system in a fourth embodiment.

FIG. 11 is a schematic diagram illustrating an example of a wirelesscommunication device that implements functions of the base station orthe terminal.

DESCRIPTION OF EMBODIMENTS

Embodiments of a base station, a terminal, a wireless communicationsystem, a method of controlling the base station, and a method ofcontrolling the terminal disclosed in the present application will bedescribed in detail below based on the drawings. The disclosedtechnology is not limited by the embodiments described below.Furthermore, the embodiments may be combined as appropriate, so long asprocessing contents do not conflict with each other.

First Embodiment

[Wireless Communication System 10]

FIG. 1 is a schematic diagram illustrating an example of a wirelesscommunication system 10. The wireless communication system 10 includes abase station 20, a base station 22, and a terminal 30. The base station20 performs wireless communication based on LTE, for example. The basestation 20 is an evolved Node B (eNB) as defined in LTE, for example.The terminal 30 is a user equipment (UE) as defined in LTE, for example.The terminal 30 belongs to the same cell managed by the base station 20,and communicates with the base station 20 in the cell. In the followingdescriptions, the base station 20 and the terminal 30 may be describedas an LTE system.

The base station 22 is, for example, a base station that belongs to asystem different from the LTE system to which the base station 20belongs. The base station 22 is, for example, a base station thatbelongs to an LTE system of a provider different from the LTE system towhich the base station 20 belongs, or a base station that belongs to adifferent communication system such as a wireless LAN system.

The base station 20 performs wireless communication with the terminal 30in the cell by using a first band dedicated to the LTE system to whichthe base station 20 belongs and a second band shared by the LTE systemto which the base station 20 belongs and other communication systems.The first band is a licensed band carrier (LC) of 2 GHz band, forexample. The second band is an unlicensed band carrier (UC) of 5 GHzband, for example. Hereinafter, the first band is referred to as alicensed band and the second band is referred to as an unlicensed band.

In the LTE system to which the base station 20 belongs, the first bandis assigned to a primary component carrier (PCC), for example, and thesecond band is assigned to a secondary component carrier (SCC), forexample. In the first embodiment, the first band is a band dedicated tothe LTE system to which the base station 20 belongs, and the second bandis a shared band shared by the LTE system to which the base station 20belongs and the communication system to which the base station 22belongs.

Furthermore, in FIG. 1, a reference sign 21 indicates an area in whichradio waves transmitted from arbitrary devices reach the base station 20at intensities that are determined as busy by carrier sense of the basestation 20. Moreover, a reference sign 23 indicates an area in whichradio waves transmitted from arbitrary devices reach the base station 22at intensities that are determined as busy by carrier sense of the basestation 22.

The base station 20, when requesting the terminal 30 to perform a ULtransmission using the unlicensed band, transmits a UL grant includinginformation on a resource used for the UL transmission to the terminal30 in the licensed band. The base station 20 then performs LBT in theunlicensed band at a timing before the timing of the UL transmissionperformed by the terminal 30. When determining that the unlicensed bandis idle, the base station 20 transmits a permission signal in theunlicensed band. In the first embodiment, the permission signal is aclear to send (CTS) signal, for example. By transmitting the permissionsignal, a band in the unlicensed band to be used by the terminal 30 forthe UL transmission is reserved for the terminal 30. The terminal 30that has received the UL grant, upon detecting the permission signal inthe unlicensed band, performs the UL transmission by using the resourceof the unlicensed band specified by the UL grant.

[Operation of Wireless Communication System 10]

Next, with reference to FIG. 2 and FIG. 3, an example of operationperformed when the terminal 30 performs the UL transmission in theunlicensed band in response to an instruction from the base station 20will be described. FIG. 2 and FIG. 3 are diagrams illustrating anexample of the operation performed by the wireless communication system10 in the first embodiment. FIG. 2 illustrates a case in which theunlicensed band is detected to be idle when the base station 20 performsLBT, and FIG. 3 illustrates a case in which the unlicensed band isdetected to be busy when the base station 20 performs LBT.

In FIG. 2 and FIG. 3, upper parts indicate signals transmitted by usingthe LC, and lower parts indicate signals transmitted by using the UC.Furthermore, in FIG. 2 and FIG. 3, the horizontal axes indicate the flowof time, and t1 to t5 indicate periods in units of a subframe (forexample, 1 millisecond). The unlicensed band is divided into a pluralityof sub-bands as illustrated in FIG. 2 and FIG. 3 for example. In thefirst embodiment, the unlicensed band is 20 MHz for example, and isdivided into four sub-bands by 5 MHz for example.

As illustrated in FIG. 2 for example, the base station 20 generates a ULgrant 40 for requesting a UL transmission when a data transmissionrequest to the terminal 30 is issued. The base station 20 then transmitsthe generated UL grant 40 to the terminal 30 in the licensed band. Inthe example illustrated in FIG. 2, for example, the base station 20transmits UL grants 40-1 to 40-5 respectively to the five terminals 30in the corresponding subframe periods t1 to t5.

The UL grant 40 includes identification information, information on asub-band, an offset, and time limit information. The identificationinformation included in the UL grant 40 has the same value asidentification information included in the permission signal that isused as a reference when the terminal 30 performs the UL transmission.Furthermore, the identification information includes a cell ID foridentifying the cell of the base station 20 that transmits the UL grant40 and the permission signal. By including the cell ID in theidentification information, even when a plurality of the base stations20 transmit permission signals, the terminal 30 can identify apermission signal to be used as a reference for the UL transmission. Thecell ID is an example of base station identification information.

The information on the sub-band included in the UL grant 40 indicates asub-band that is a resource of the unlicensed band to be used when theterminal 30 performs the UL transmission. Furthermore, the offsetincluded in the UL grant 40 indicates a time from the permission signalto a start of the UL transmission. In the first embodiment, the offsetis specified in units of a subframe in LTE, for example. Moreover, thetime limit information included in the UL grant 40 indicates a timelimit for the terminal 30 to wait for the permission signal. In thefirst embodiment, the time limit information is specified in units of asubframe with reference to a subframe in which the UL grant 40 istransmitted, for example. In the first embodiment, the time limitspecified by the time limit information is a timing ten subframes afterthe subframe in which the UL grant 40 is transmitted, for example.

The base station 20, when causing a plurality of the terminals 30 toperform the UL transmission in consecutive subframes, sets theidentification information included in the respective UL grants 40 tothe same value. Furthermore, the base station 20, when causing aplurality of the terminals 30 to perform the UL transmission inconsecutive subframes, sequentially shifts the offsets included in theUL grants 40 to be transmitted to the respective terminals 30 by apredetermined time (for example, a time of one subframe).

In the example illustrated in FIG. 2, for example, the UL grant 40-1includes, as the offset, a value of “1” indicating that the ULtransmission is performed in the first subframe after the subframe inwhich the permission signal is transmitted. Similarly, for example, theUL grant 40-5 includes, as the offset, a value of “5” indicating thatthe UL transmission is performed in the fifth subframe after thesubframe in which the permission signal is transmitted.

Subsequently, the base station 20 performs LBT in the unlicensed band apredetermined time after transmission of the UL grant 40 (for example,after three subframes). Then, upon detecting that the unlicensed band isidle and confirming that the idle state is continued during a backoffperiod 41, the base station 20 transmits permission signals 42 in all ofthe sub-bands in the unlicensed band. The permission signals 42 includeidentification information for identifying the respective permissionsignals 42. For example, the permission signals 42 are transmitted inthe unlicensed band in a certain length such that a period 43 of a shortinter-frame space (SIFS) after completion of the transmission of thepermission signals 42 ends at a timing of border between the subframe inwhich the permission signals 42 are transmitted and a next subframe.

Upon receiving the UL grant 40 in the licensed band, the terminal 30acquires the identification information, the information on thesub-band, the offset, and the time limit information from the UL grant40. Furthermore, upon receiving the permission signal 42 in theunlicensed band, the terminal 30 acquires the identification informationfrom the permission signal 42. Then, after a lapse of a time specifiedby the offset acquired from the UL grant 40 with reference to the timingat which the permission signal 42 is received, the terminal 30 performsa UL transmission of a signal 44 by using the sub-band of the unlicensedband specified by the UL grant 40.

In the example illustrated in FIG. 2, for example, the terminal 30 thathas received the UL grant 40-1 including the offset with a value of “1”performs a UL transmission of a signal 44-1 in the subframe period t5that is the first subframe after the subframe period t4 in which thepermission signal 42 is transmitted. Similarly, the terminal 30 that hasreceived the UL grant 40-5 including the offset with a value of “5”performs a UL transmission of a signal 44-5 in the subframe period t9that is the fifth subframe after the subframe period t4 in which thepermission signal 42 is transmitted.

Furthermore, as illustrated in FIG. 3 for example, when another signal45 is transmitted in the unlicensed band in the period t4 after a lapseof a predetermined time since the transmission of the UL grant 40, thebase station 20 detects that the unlicensed band is busy by LBT. Thebase station 20 then continues the LBT in the unlicensed band. Then, asillustrated in FIG. 3 for example, upon detecting that the unlicensedband is idle in the period t5, the base station 20 confirms whether theidle state is continued during a period 46 of a Distributed coordinationfunction Inter Frame Space (DIFS). If it is confirmed that the idlestate is continued during the period 46, the base station 20 confirmswhether the idle state is continued during the backoff period 41, andafter confirming that the idle state is continued, transmits thepermission signal 42 in the unlicensed band.

After a lapse of a time specified by the offset acquired from the ULgrant 40 with reference to the timing at which the permission signal 42is received, each of the terminals 30 performs the UL transmission ofthe signal 44 by using the sub-band of the unlicensed band specified bythe UL grant 40. Therefore, as indicated by arrows in FIG. 3 forexample, all of the timings of the UL transmissions of the signals 44-1to 44-5 by the respective terminals 30 are shifted backward due to thedelay of the transmission of the permission signals 42.

Incidentally, when it is determined that the unlicensed band is busy atthe timing of the LBT, and if the base station 20 stops transmission ofthe permission signal 42 and retransmits the UL grant 40, the ULtransmission is suspended until a predetermined time elapses after anext UL grant 40. Consequently, a throughput of data transmission in theuplink is reduced.

In contrast, the base station 20 of the first embodiment continues theLBT even when it is determined that the unlicensed band is busy by theLBT, and transmits the permission signal 42 in the unlicensed band whenit is detected that the unlicensed band is idle. Therefore, even whenthe UL grant 40 is not retransmitted, the terminal 30 can perform the ULtransmission with reference to the timing at which the permission signal42 is transmitted. Consequently, the wireless communication system 10can improve the throughput of data in the uplink from the terminal 30 tothe base station 20. Furthermore, it is possible to reduceretransmission of the UL grant, so that it is possible to reduce thetraffic of a control signal in the licensed band.

Incidentally, when causing a plurality of the terminals 30 to performthe UL transmission in consecutive subframes, the base station 20adjusts the offsets that specify the timings of the UL transmissionsperformed by the respective terminals 30 with reference to the singlepermission signal 42. Consequently, in some cases, the permission signal42 may be transmitted before the UL grant 40 depending on the timing oftransmission of the permission signal 42. Therefore, each of theterminals 30 waits to receive the permission signal 42 in the unlicensedband before receiving the UL grant 40 in the licensed band. Then, uponreceiving both of the UL grant 40 and the permission signal 42, each ofthe terminals 30 performs the UL transmission at the timing specified bythe offset in the UL grant 40 with reference to the timing at which thepermission signal 42 is transmitted.

[Base Station 20]

FIG. 4 is a block diagram illustrating an example of the base station20. The base station 20 includes a packet generating unit 200, a mediaaccess control (MAC) scheduling unit 201, a MAC control unit 202, and aradio resource control (RRC) control unit 203. Furthermore, the basestation 20 includes a MAC/radio link control (RLC) processing unit 204,a determining unit 205, and a measuring unit 206. Moreover, the basestation 20 includes an unlicensed band transmitting unit 210, a licensedband transmitting unit 220, an unlicensed band receiving unit 230, alicensed band receiving unit 240, an antenna 216, an antenna 226, anantenna 235, and an antenna 245. Incidentally, in the first embodiment,the antenna 216, the antenna 226, the antenna 235, and the antenna 245are implemented by separate antennas; however, as another example, theantennas may be implemented by a single antenna.

The licensed band receiving unit 240 performs a process of decoding datafrom a signal received in the licensed band. The licensed band receivingunit 240 includes a decoding unit 241, a demodulating unit 242, an FFTprocessing unit 243, and a wireless processing unit 244.

The wireless processing unit 244 performs a wireless process on a signalreceived via the antenna 245. The wireless process performed by thewireless processing unit 244 includes, for example, a process ofconverting the frequency of the received signal from the frequency ofthe licensed band to the frequency of the baseband. The wirelessprocessing unit 244 outputs the received signal subjected to thewireless process to the FFT processing unit 243.

The FFT processing unit 243 performs a fast Fourier transform (FFT)process on the received signal output from the wireless processing unit244. Consequently, the received signal subjected to the frequencyconversion from the licensed band to the baseband is converted from thetime domain to the frequency domain. The FFT processing unit 243 outputsthe received signal subjected to the FFT process to the demodulatingunit 242.

The demodulating unit 242 demodulates the received signal output fromthe FFT processing unit 243. Then, the demodulating unit 242 outputs thereceived signal subjected to the demodulation to the decoding unit 241.The decoding unit 241 decodes the received signal output from thedemodulating unit 242. Then, the decoding unit 241 outputs the decodeddata to the MAC/RLC processing unit 204.

The unlicensed band receiving unit 230 performs a process of decodingdata from a signal received in the unlicensed band. The unlicensed bandreceiving unit 230 includes a decoding unit 231, a demodulating unit232, an FFT processing unit 233, and a wireless processing unit 234.

The wireless processing unit 234 performs a wireless process on a signalreceived via the antenna 235. The wireless process performed by thewireless processing unit 234 includes, for example, a process ofconverting the frequency of the received signal from the frequency ofthe unlicensed band to the frequency of the baseband. The wirelessprocessing unit 234 outputs the received signal subjected to thewireless process to the FFT processing unit 233.

The FFT processing unit 233 performs an FFT process on the receivedsignal output from the wireless processing unit 234. Consequently, thereceived signal subjected to the frequency conversion from theunlicensed band to the baseband is converted from the time domain to thefrequency domain. The FFT processing unit 233 outputs the receivedsignal subjected to the FFT process to the demodulating unit 232 and themeasuring unit 206.

The demodulating unit 232 demodulates the received signal output fromthe FFT processing unit 233. Then, the demodulating unit 232 outputs thereceived signal subjected to the demodulation to the decoding unit 231.The decoding unit 231 decodes the received signal output from thedemodulating unit 232. Then, the decoding unit 231 outputs the decodeddata to the MAC/RLC processing unit 204.

The measuring unit 206 measures interference power in the unlicensedband on the basis of the received signal output from the FFT processingunit 233. Then, the measuring unit 206 outputs a measurement result ofthe interference power to the determining unit 205.

The determining unit 205 determines whether the unlicensed band is idleor busy on the basis of the measurement result output from the measuringunit 206. Then, the determining unit 205 outputs a determination resultto the MAC control unit 202.

The MAC/RLC processing unit 204 performs a process in the MAC layer anda process in the RLC layer on the basis of the data output from thedecoding unit 231 and the decoding unit 241. The MAC/RLC processing unit204 outputs data obtained through the processes in the respective layersto, for example, a higher-level device of the base station 20.Furthermore, the MAC/RLC processing unit 204 outputs control informationincluded in the data obtained through the processes in the respectivelayers to the RRC control unit 203.

The RRC control unit 203 performs radio resource control on the basis ofthe control information output from the MAC/RLC processing unit 204. Theradio resource control performed by the RRC control unit 203 is aprocess in the RRC layer. The RRC control unit 203 generates controlinformation on the basis of the radio resource control, and outputs thegenerated control information to the MAC control unit 202.

The MAC control unit 202 controls the MAC layer on the basis of thecontrol information output from the RRC control unit 203 and thedetermination result output from the determining unit 205. Then, the MACcontrol unit 202 generates control information on the basis of thecontrol on the MAC layer, and outputs the generated control informationto the MAC scheduling unit 201.

Furthermore, when a data transmission request to the terminal 30 isissued, the MAC control unit 202 generates a UL grant for requesting aUL transmission. Then, the MAC control unit 202 outputs the generated ULgrant to a multiplexing unit 223 to be described later.

Moreover, when the data transmission request to the terminal 30 isissued, the MAC control unit 202 performs LBT in the unlicensed band onthe basis of the determination result output from the determining unit205 before the timing of the UL transmission. Then, upon detecting thatthe unlicensed band is idle, the MAC control unit 202 generates apermission signal, and outputs the generated permission signal to amultiplexing unit 213.

The packet generating unit 200 generates a packet including user dataoutput from a higher-level device. Then, the packet generating unit 200outputs the generated packet to the MAC scheduling unit 201.

The MAC scheduling unit 201 performs scheduling in the MAC layer withrespect to the packet output from the packet generating unit 200, on thebasis of the control information output from the MAC control unit 202.Then, the MAC scheduling unit 201 controls output of the packetgenerated by the packet generating unit 200 to the unlicensed bandtransmitting unit 210 or to the licensed band transmitting unit 220, onthe basis of a result of the scheduling.

The licensed band transmitting unit 220 performs a process oftransmitting data in the licensed band. The licensed band transmittingunit 220 includes an encoding unit 221, a modulating unit 222, themultiplexing unit 223, an inverse fast Fourier transform (IFFT)processing unit 224, and a wireless processing unit 225.

The encoding unit 221 encodes data of the packet output from the MACscheduling unit 201. Then, the encoding unit 221 outputs the encodeddata of the packet to the modulating unit 222. The modulating unit 222modulates the data output from the encoding unit 221. Then, themodulating unit 222 outputs a modulated signal to the multiplexing unit223.

The multiplexing unit 223 multiplexes the control signal such as the ULgrant output from the MAC control unit 202 and the signal output fromthe modulating unit 222. Then, the multiplexing unit 223 outputs themultiplexed transmission signal to the IFFT processing unit 224.

The IFFT processing unit 224 performs an IFFT process on thetransmission signal output from the multiplexing unit 223. Consequently,the transmission signal output from the multiplexing unit 223 isconverted from the frequency domain to the time domain. The IFFTprocessing unit 224 outputs the transmission signal subjected to theIFFT process to the wireless processing unit 225.

The wireless processing unit 225 performs a wireless process on thetransmission signal output from the IFFT processing unit 224. Thewireless process performed by the wireless processing unit 225 includes,for example, a process of converting the frequency of the transmissionsignal from the frequency of the baseband to the frequency of thelicensed band. The wireless processing unit 225 transmits thetransmission signal subjected to the wireless process from the antenna226.

The unlicensed band transmitting unit 210 performs a process oftransmitting data in the unlicensed band. The unlicensed bandtransmitting unit 210 includes an encoding unit 211, a modulating unit212, the multiplexing unit 213, an IFFT processing unit 214, and awireless processing unit 215.

The encoding unit 211 encodes the data of the packet output from the MACscheduling unit 201. Then, the encoding unit 211 outputs the encodeddata of the packet to the modulating unit 212. The modulating unit 212modulates the data of the packet output from the encoding unit 211.Then, the modulating unit 212 outputs a modulated signal to themultiplexing unit 213.

The multiplexing unit 213 multiplexes the signal such as the permissionsignal output from the MAC control unit 202 and the signal output fromthe modulating unit 212. Then, the multiplexing unit 213 outputs themultiplexed transmission signal to the IFFT processing unit 214.

The IFFT processing unit 214 performs an IFFT process on thetransmission signal output from the multiplexing unit 213. Consequently,the transmission signal output from the multiplexing unit 213 isconverted from the frequency domain to the time domain. The IFFTprocessing unit 214 outputs the transmission signal subjected to theIFFT process to the wireless processing unit 215.

The wireless processing unit 215 performs a wireless process on thetransmission signal output from the IFFT processing unit 214. Thewireless process performed by the wireless processing unit 215 includes,for example, a process of converting the frequency of the transmissionsignal from the frequency of the baseband to the frequency of theunlicensed band. The wireless processing unit 215 transmits thetransmission signal subjected to the wireless process from the antenna216.

[Terminal 30]

FIG. 5 is a block diagram illustrating an example of the terminal 30.The terminal 30 includes an antenna 300, a decoding unit 301, an RRCprocessing unit 304, an uplink managing unit 305, an encoding/modulatingunit 306, and a packet generating unit 307. Furthermore, the terminal 30includes a licensed band receiving unit 310, an unlicensed bandreceiving unit 320, an unlicensed band transmitting unit 330, and alicensed band transmitting unit 340.

Incidentally, in the first embodiment, the terminal 30 includes thesingle antenna 300. However, as another example, the antenna 300 mayseparately be provided in each of the licensed band receiving unit 310,the unlicensed band receiving unit 320, the unlicensed band transmittingunit 330, and the licensed band transmitting unit 340.

The licensed band receiving unit 310 performs a process of demodulatingdata from a signal received in the licensed band. The licensed bandreceiving unit 310 includes a wireless processing unit 311, an FFTprocessing unit 312, an equalization processing unit 313, an IFFTprocessing unit 314, and a demodulating unit 315.

The wireless processing unit 311 performs a wireless process on a signalreceived via the antenna 300. The wireless process performed by thewireless processing unit 311 includes, for example, a process ofconverting the frequency of the received signal from the frequency ofthe licensed band to the frequency of the baseband. The wirelessprocessing unit 311 outputs the received signal subjected to thewireless process to the FFT processing unit 312.

The FFT processing unit 312 performs an FFT process on the receivedsignal output from the wireless processing unit 311. Consequently, thereceived signal output from the wireless processing unit 311 isconverted from the time domain to the frequency domain. The FFTprocessing unit 312 outputs the received signal subjected to the FFTprocess to the equalization processing unit 313. The equalizationprocessing unit 313 performs an equalization process on the signaloutput from the FFT processing unit 312. Then, the equalizationprocessing unit 313 outputs the received signal subjected to theequalization process to the IFFT processing unit 314.

The IFFT processing unit 314 performs an IFFT process on the receivedsignal output from the equalization processing unit 313. Consequently,the received signal output from the equalization processing unit 313 isconverted from the frequency domain to the time domain. The IFFTprocessing unit 314 outputs the received signal subjected to the IFFTprocess to the demodulating unit 315.

The demodulating unit 315 demodulates the received signal output fromthe IFFT processing unit 314. Then, the demodulating unit 315 outputsthe received signal subjected to the demodulation to the decoding unit301. Data decoded from the received signal demodulated by the licensedband receiving unit 310 includes a control signal such as the UL grant.

The unlicensed band receiving unit 320 performs a process ofdemodulating data from a signal received in the unlicensed band. Theunlicensed band receiving unit 320 includes a wireless processing unit321, an FFT processing unit 322, an equalization processing unit 323, anIFFT processing unit 324, and a demodulating unit 325.

The wireless processing unit 321 performs a wireless process on a signalreceived via the antenna 300. The wireless process performed by thewireless processing unit 321 includes, for example, a process ofconverting the frequency of the received signal from the frequency ofthe unlicensed band to the frequency of the baseband. The wirelessprocessing unit 321 outputs the received signal subjected to thewireless process to the FFT processing unit 322.

The FFT processing unit 322 performs an FFT process on the receivedsignal output from the wireless processing unit 321. Consequently, thereceived signal output from the wireless processing unit 321 isconverted from the time domain to the frequency domain. Then, the FFTprocessing unit 322 outputs the received signal subjected to the FFTprocess to the equalization processing unit 323. The equalizationprocessing unit 323 performs an equalization process on the receivedsignal output from the FFT processing unit 322. Then, the equalizationprocessing unit 323 outputs the received signal subjected to theequalization process to the IFFT processing unit 324.

The IFFT processing unit 324 performs an IFFT process on the receivedsignal output from the equalization processing unit 323. Consequently,the received signal output from the equalization processing unit 323 isconverted from the frequency domain to the time domain. The IFFTprocessing unit 324 outputs the received signal subjected to the IFFTprocess to the demodulating unit 325.

The demodulating unit 325 demodulates the received signal output fromthe IFFT processing unit 324. Then, the demodulating unit 325 outputsthe received signal subjected to the demodulation to the decoding unit301. Data decoded from the received signal demodulated by the unlicensedband receiving unit 320 includes a control signal such as the permissionsignal.

The decoding unit 301 decodes user data and a control signal from thereceived signal output from the licensed band receiving unit 310 and theunlicensed band receiving unit 320. Then, the decoding unit 301 outputsthe decoded user data to, for example, an application processing unit(not illustrated) that performs a process based on the received data.Furthermore, the decoding unit 301 outputs the decoded control signal tothe RRC processing unit 304 and the uplink managing unit 305. Thecontrol signal output to the uplink managing unit 305 includes the ULgrant and the permission signal.

The RRC processing unit 304 performs radio resource control on the basisof the control signal output from the decoding unit 301. The radioresource control performed by the RRC processing unit 304 is a processin the RRC layer. The RRC processing unit 304 generates controlinformation on the basis of the radio resource control, and outputs thegenerated control information to the uplink managing unit 305.

The uplink managing unit 305 controls the UL transmission on the basisof the control information output from the RRC processing unit 304 andthe control signal output from the decoding unit 301. For example, whenthe decoding unit 301 outputs a UL grant, the uplink managing unit 305acquires the identification information, the information on the sub-bandin the unlicensed band, the offset, and the time limit information fromthe UL grant. Furthermore, when the decoding unit 301 outputs apermission signal, the uplink managing unit 305 acquires theidentification information included in the permission signal.

Moreover, when a permission signal including the same identificationinformation as the identification information acquired from the UL grantis detected in the unlicensed band, the uplink managing unit 305determines whether a time corresponding to the offset included in the ULgrant has elapsed since the detection of the permission signal. If thetime corresponding to the offset has elapsed since the detection of thepermission signal, the uplink managing unit 305 outputs a control signalsuch as a DMRS to a multiplexing unit 335 and a multiplexing unit 345.

Furthermore, the uplink managing unit 305 outputs information onassignment of a resource used for the UL transmission to a frequencymapping unit 333 and a frequency mapping unit 343 to be described later.Moreover, if the time corresponding to the offset has elapsed sincedetection of the permission signal, the uplink managing unit 305instructs the encoding/modulating unit 306 (to be described later) toperform the UL transmission.

The packet generating unit 307 generates, for example, a packetincluding user data output from the application processing unit (notillustrated). Then, the packet generating unit 307 outputs the generatedpacket to the encoding/modulating unit 306. The encoding/modulating unit306 performs an encoding/modulating process on the packet output fromthe packet generating unit 307. Then, the encoding/modulating unit 306outputs a transmission signal subjected to the encoding/modulatingprocess to the unlicensed band transmitting unit 330 or the licensedband transmitting unit 340 in accordance with an instruction from theuplink managing unit 305.

The licensed band transmitting unit 340 performs a process oftransmitting data in the licensed band. The licensed band transmittingunit 340 includes a wireless processing unit 341, an IFFT processingunit 342, the frequency mapping unit 343, an FFT processing unit 344,and the multiplexing unit 345.

The multiplexing unit 345 multiplexes the control signal output from theuplink managing unit 305 and the transmission signal output from theencoding/modulating unit 306. Then, the multiplexing unit 345 outputsthe multiplexed transmission signal to the FFT processing unit 344. TheFFT processing unit 344 performs the FFT process on the transmissionsignal output from the multiplexing unit 345. Consequently, thetransmission signal output from the multiplexing unit 345 is convertedfrom the time domain to the frequency domain. The FFT processing unit344 outputs the transmission signal subjected to the FFT process to thefrequency mapping unit 343.

The frequency mapping unit 343 performs frequency mapping on thetransmission signal output from the FFT processing unit 344, on thebasis of the information on assignment of a resource used for the ULtransmission, which is output from the uplink managing unit 305. Then,the frequency mapping unit 343 outputs the transmission signal subjectedto the frequency mapping to the IFFT processing unit 342.

The IFFT processing unit 342 performs an IFFT process on thetransmission signal output from the frequency mapping unit 343.Consequently, the transmission signal output from the frequency mappingunit 343 is converted from the frequency domain to the time domain. TheIFFT processing unit 342 outputs the transmission signal subjected tothe IFFT process to the wireless processing unit 341.

The wireless processing unit 341 performs a wireless process on thetransmission signal output from the IFFT processing unit 342. Thewireless process performed by the wireless processing unit 341 includes,for example, a process of converting the frequency of the transmissionsignal from the frequency of the baseband to the frequency of thelicensed band. The wireless processing unit 341 transmits thetransmission signal subjected to the wireless process via the antenna300.

The unlicensed band transmitting unit 330 performs a process oftransmitting data in the unlicensed band. The unlicensed bandtransmitting unit 330 includes a wireless processing unit 331, an IFFTprocessing unit 332, the frequency mapping unit 333, an FFT processingunit 334, and the multiplexing unit 335.

The multiplexing unit 335 multiplexes the control signal output from theuplink managing unit 305 and the signal output from theencoding/modulating unit 306. Then, the multiplexing unit 335 outputsthe multiplexed transmission signal to the FFT processing unit 334. TheFFT processing unit 334 performs the FFT process on the transmissionsignal output from the multiplexing unit 335. Consequently, thetransmission signal output from the multiplexing unit 335 is convertedfrom the time domain to the frequency domain. The FFT processing unit334 outputs the transmission signal subjected to the FFT process to thefrequency mapping unit 333.

The frequency mapping unit 333 performs frequency mapping on thetransmission signal output from the FFT processing unit 334, on thebasis of the information on assignment of a resource used for the ULtransmission, which is output from the uplink managing unit 305. Then,the frequency mapping unit 333 outputs the transmission signal subjectedto the frequency mapping to the IFFT processing unit 332.

The IFFT processing unit 332 performs an IFFT process on thetransmission signal output from the frequency mapping unit 333.Consequently, the transmission signal output from the frequency mappingunit 333 is converted from the frequency domain to the time domain. TheIFFT processing unit 332 outputs the transmission signal subjected tothe IFFT process to the wireless processing unit 331.

The wireless processing unit 331 performs a wireless process on thetransmission signal output from the IFFT processing unit 332. Thewireless process performed by the wireless processing unit 331 includes,for example, a process of converting the frequency of the transmissionsignal from the frequency of the baseband to the frequency of theunlicensed band. The wireless processing unit 331 outputs thetransmission signal subjected to the wireless process via the antenna300.

[Operation of Base Station 20]

Next, operation of the base station 20 will be described. FIG. 6 andFIG. 7 are flowcharts illustrating an example of the operation performedby the base station 20.

First, the MAC control unit 202 of the base station 20 initializes avariable i to 1 (S100). Then, the MAC control unit 202 determineswhether a data transmission request to the terminal 30 is issued (S101).If the data transmission request to the terminal 30 is issued (Yes atS101), the MAC control unit 202 determines whether all of ULtransmissions specified by UL grants that include i−1 as theidentification information are completed or cancelled (S102).

If there is a UL transmission that is not completed or cancelled amongthe UL transmissions specified by the UL grants that include i−1 as theidentification information (No at S102), the MAC control unit 202increments a variable j by 1 (S105). Then, the MAC control unit 202generates a UL grant including an offset j indicating that the value ofthe offset is j, identification information including i−1 and a cell ID,and time limit information. Then, the MAC control unit 202 instructs thelicensed band transmitting unit 220 to transmit the generated UL grantto the terminal 30 in the licensed band (S106). Then, the MAC controlunit 202 performs the process at Step S101 again.

If all of the UL transmissions specified by the UL grants that includei−1 as the identification information are completed or cancelled (Yes atS102), the MAC control unit 202 initializes the variable j to 1 (S103).Then, the MAC control unit 202 generates a UL grant including the offsetj, identification information including i and the cell ID, and the timelimit information. Then, the MAC control unit 202 instructs the licensedband transmitting unit 220 to transmit the generated UL grant to theterminal 30 in the licensed band (S104).

Subsequently, the MAC control unit 202 determines whether apredetermined time (for example, a time corresponding to threesubframes) has elapsed since the transmission of the UL grant (S107 inFIG. 7). If the predetermined time has elapsed since the transmission ofthe UL grant (Yes at S107), the MAC control unit 202 performs LBT in theunlicensed band and determines whether the unlicensed band is idle(S108).

If the unlicensed band is idle (Yes at S108), the MAC control unit 202generates a permission signal that includes identification informationincluding i and the cell ID. Then, the MAC control unit 202 instructsthe unlicensed band transmitting unit 210 to transmit the generatedpermission signal to the unlicensed band (S109). Then, the MAC controlunit 202 increments the variable i by 1 (S110), and performs the processat Step S101 illustrated in FIG. 6 again.

If the predetermined time has not elapsed since the transmission of theUL grant (No at S107), or if the unlicensed band is busy (No at S108),the MAC control unit 202 determines whether a data transmission requestto the terminal 30 is issued (S111. If the data transmission request tothe terminal 30 is issued (Yes at S111), the MAC control unit 202increments the variable j by 1 (S112). Then, the MAC control unit 202generates a UL grant including the offset j, identification informationincluding i and the cell ID, and the time limit information. Then, theMAC control unit 202 instructs the licensed band transmitting unit 220to transmit the generated UL grant to the terminal 30 in the licensedband (S113). Then, the MAC control unit 202 performs the process at StepS107 again.

Furthermore, if the data transmission request to the terminal 30 is notissued (No at S111), the MAC control unit 202 identifies a UL grantcorresponding to a UL transmission that has not been performed. Then,the MAC control unit 202 determines whether a time limit indicated bythe time limit information has passed since the transmission of theidentified UL grant (S114). If the time limit has not passed (No atS114), the MAC control unit 202 performs the process at Step S107 again.

If the time limit indicated by the time limit information has passedsince the transmission of the UL grant (Yes at S114), the MAC controlunit 202 cancels the data transmission request that is provided to theterminal 30 by the UL grant (S115), and performs the process at StepS110.

Incidentally, if there is a UL transmission that is not completed orcancelled among the UL transmissions specified by the transmitted ULgrants as described above (No at S102), the base station 20 transmits aUL grant that includes i−1 as the identification information (S106).Therefore, the base station 20 can cause the terminal 30 to use thealready-transmitted permission signal including the identificationinformation of i−1 at Step S109. Consequently, the base station 20 cancause the terminals 30 to perform the increased number of ULtransmissions with the decreased number of the permission signals.

[Operation of Terminal 30]

Next, operation of the terminal 30 will be described. FIG. 8 is aflowchart illustrating an example of the operation performed by theterminal 30.

First, the uplink managing unit 305 determines whether a UL grant isreceived in the licensed band (S200). If the UL grant is received (Yesat S200), the uplink managing unit 305 acquires the identificationinformation, the offset, and the time limit information from the ULgrant (S201).

Subsequently, the uplink managing unit 305 determines whether apermission signal including the same identification information as theidentification information included in the UL grant is received (S202).Incidentally, the permission signal may be received before the UL grant.If the permission signal including the same identification informationas the identification information included in the UL grant is received(Yes at S202), the uplink managing unit 305 waits until a time indicatedby the offset acquired from the UL grant elapses after the timing atwhich the permission signal is received (S203).

Subsequently, the uplink managing unit 305 provides the information onassignment of a resource specified by the UL grant to the unlicensedband transmitting unit 330. Then, the uplink managing unit 305 instructsthe encoding/modulating unit 306 to perform a UL transmission, tothereby perform the UL transmission by using the resource specified bythe UL grant (S204). Then, the uplink managing unit 305 performs theprocess at Step S200 again.

Furthermore, if the permission signal including the same identificationinformation as the identification information included in the UL grantis not received (No at S202), the uplink managing unit 305 determineswhether a time limit indicated by the time limit information acquiredfrom the UL grant has passed (S205). If the time limit has not passed(No at S205), the uplink managing unit 305 performs the process at StepS202 again. In contrast, if the time limit has passed (Yes at S205), theuplink managing unit 305 cancels the UL transmission specified by the ULgrant and performs the process at Step S200 again. By cancelling the ULtransmission for which the time limit has passed, it is possible toprevent an increase in the power consumption of the terminal 30 due tothe continued wait for the permission signal.

The first embodiment has been described above. As is clear from theabove, according to the wireless communication system 10 of the firstembodiment, it is possible to suppress a reduction in the throughput inthe uplink.

Second Embodiment

In the above-described first embodiment, the base station 20 transmitsthe UL grant 40 to the terminal 30 in the licensed band. In contrast, ina second embodiment, the base station 20 transmits the UL grant 40 tothe terminal 30 in the unlicensed band. However, in the unlicensed band,each communication apparatus performs transmission after detecting thata band is vacant. Therefore, in the second embodiment, when a datatransmission request to the terminal 30 is issued, the base station 20performs LBT in the unlicensed band, detects that the band is vacant,and thereafter transmits the UL grant 40 to the terminal 30.

Third Embodiment

In the above-described first embodiment, when it is detected that theunlicensed band is busy as a result of LBT performed before transmissionof a permission signal, the base station 20 suspends the transmission ofthe permission signal until it is detected that the unlicensed band isidle. However, in the unlicensed band, in some cases, data transmissionin a downlink (DL) from the base station 20 to the terminal 30 may beperformed. When the data transmission in the DL is being performed inthe unlicensed band, the unlicensed band is busy; however, the basestation 20 can generate a signal to be transmitted from the base station20 to the terminal 30. Therefore, in the third embodiment, if datatransmission from the base station 20 to the terminal 30 is performed atthe timing of the transmission of the permission signal, the permissionsignal is multiplexed and transmitted in the same subframe.Consequently, even when the data transmission in the DL is beingperformed in the unlicensed band, the base station 20 can provide thepermission signal to the terminal 30.

Incidentally, when the data transmission in the DL is being performed inthe unlicensed band, the base station 20 includes the permission signalin one of control channels that are multiplexed in the same frame as thedata transmission to the terminal 30. Examples of the control channelinclude, for example, a physical downlink control channel (PDCCH) and anenhanced PDCCH (ePDCCH). Furthermore, to enable all of the controlledterminals 30 to receive a PDCCH or an ePDCCH indicating the permissionsignal, the base station 20 provides the permission signal in a commonsearch space.

[Operation of Wireless Communication System 10]

FIG. 9 is a schematic diagram illustrating an example of operationperformed by the wireless communication system 10 in the thirdembodiment. As illustrated in FIG. 9 for example, when the other signal45 is transmitted in the unlicensed band in the subframe period t4 aftera lapse of a predetermined time since transmission of the UL grant 40-1,the base station 20 detects that the unlicensed band is busy by LBT.Then, the base station 20 suspends transmission of the permissionsignal.

Meanwhile, the base station 20 performs LBT for the unlicensed band inorder to transmit DL data to any of the controlled terminals 30 in thesubframe period t5. Then, as illustrated in FIG. 9 for example, upondetecting that the unlicensed band is idle in the period t4, the basestation 20 confirms whether the idle state is continued during theperiod 46 of the DIFS. If it is confirmed that the idle state iscontinued during the period 46, the base station 20 confirms that theidle state is continued during the random backoff period 41, andthereafter transmits DL data 47 in the unlicensed band in the subframeperiod t5.

At this time, the base station 20 includes the permission single in oneof control channels 48 that are multiplexed with the DL data 47transmitted in the subframe period t5, and transmits the permissionsignal in the unlicensed band. For example, a PDCCH that is the controlchannel 48 is transmitted in the predetermined number of symbols fromthe top of the subframe (for example, three symbols from the top at amaximum).

Each of the terminals 30 that has received the control channel 48 in theunlicensed band detects the permission signal from the control channel48. Then, each of the terminals 30 transmits one of the signals 44-1 to44-4 in the sub-band of the unlicensed band specified by the UL grant 40after a lapse of a time specified by the offset acquired from the ULgrant 40 with reference to the subframe in which the permission signalis detected. Therefore, the base station 20 can transmit the permissionsignal in the subframe in which the DL data is transmitted, withoutwaiting for the transmission of the permission signal until thetransmission of the DL data is completed. Accordingly, each of theterminals 30 can start the UL transmission after completion of thetransmission of the DL data; therefore, it is possible to improve thethroughput of data transmission in the uplink.

Incidentally, a control signal such as a DL assignment indicatingassignment of a resource of the DL data is transmitted by using one ofthe control channels multiplexed with the DL data in the unlicensedband, for example. Furthermore, for another example, a control signalsuch as the DL assignment may be transmitted to each of the terminals 30by using a control channel transmitted in the same subframe as the DLdata in the licensed band, for example.

Fourth Embodiment

In the above-described third embodiment, the base station 20 includesthe permission signal in the control channel multiplexed in the samesubframe as the DL data when the DL data is transmitted in theunlicensed band at the timing of transmitting the permission signal. Incontrast, the base station 20 of a fourth embodiment transmits thepermission signal in the licensed band in a subframe including thetiming of transmitting the permission signal when the DL data istransmitted in the unlicensed band at the timing of transmitting thepermission signal. In the fourth embodiment, for example, the permissionsignal is transmitted by using one of control channels transmitted inthe licensed band. The control channel is, for example, a PDCCH, anePDCCH, or the like.

[Operation of Wireless Communication System 10]

FIG. 10 is a schematic diagram illustrating an example of operationperformed by the wireless communication system 10 in the fourthembodiment. In FIG. 10, components denoted by the same reference signsas those in FIG. 9 are the same as the components described withreference to FIG. 3, excluding those described below; therefore, thedetailed explanation will be omitted.

The base station 20, upon detecting that the unlicensed band is idle byperforming LBT in the subframe period t4, transmits DL data in theunlicensed band in the subframe period t5. The DL data 47 is multiplexedwith a plurality of the control channels 48 that include control signalssuch as the DL assignment. Furthermore, the base station 20 transmitsthe permission signal to each of the terminals 30 by using one ofcontrol channels 49 that are transmitted in the licensed band in thesubframe period t5 in which the DL data is transmitted.

Each of the terminals 30 that has received the control channel 49 in thelicensed band detects the permission signal from the control channel 49.Then, each of the terminals 30 transmits one of the signals 44-1 to 44-4in the sub-band of the unlicensed band specified by the UL grant 40after a lapse of a time specified by the offset acquired from the ULgrant 40 with reference to the subframe in which the permission signalis detected. Even in the fourth embodiment, the base station 20 cantransmit the permission signal in the subframe in which the DL data istransmitted, without waiting for the transmission of the permissionsignal until the transmission of the DL data is completed. Therefore, itis possible to improve the throughput of data transmission in theuplink.

[Hardware]

The base station 20 and the terminal 30 in the above-describedembodiments are implemented by, for example, a wireless communicationdevice 70 illustrated in FIG. 11. FIG. 11 is a schematic diagramillustrating an example of the wireless communication device 70 thatimplements the functions of the base station 20 or the terminal 30. Thewireless communication device 70 includes, for example, a memory 71, aprocessor 72, an analog-to-digital converter (A/D) 73, a multiplier 74,an amplifier 75, an oscillator 76, a digital-to-analog converter (D/A)77, a multiplier 78, an amplifier 79, and an antenna 80. Furthermore,the wireless communication device 70 may further include an interfacefor performing communication with external communication apparatusesthrough wire.

The antenna 80 receives a wireless signal and outputs the receivedsignal to the amplifier 75. Furthermore, the antenna 80 transmits asignal output from the amplifier 79 to outside. The amplifier 75amplifies the signal received by the antenna 80, and outputs theamplified signal to the multiplier 74. The multiplier 74 multiplies thesignal output from the amplifier 75 and a clock signal output from theoscillator 76, to thereby convert the frequency of the received signalfrom the high-frequency band to the baseband. Then, the multiplier 74outputs the signal subjected to the frequency conversion to theanalog-to-digital converter 73. The analog-to-digital converter 73converts the analog received signal output from the multiplier 74 into adigital received signal, and outputs the converted received signal tothe processor 72.

The processor 72 controls the entire wireless communication device 70.The processor 72 may be implemented by, for example, a centralprocessing unit (CPU), a digital signal processor (DSP), or the like.The processor 72 performs a process of receiving a signal output fromthe analog-to-digital converter 73. Furthermore, the processor 72generates a transmission signal, and outputs the generated transmissionsignal to the digital-to-analog converter 77.

The memory 71 includes, for example, a main memory and an auxiliarymemory. The main memory is, for example, a random access memory (RAM).The main memory is used as a work area of the processor 72. Theauxiliary memory is, for example, a non-volatile memory such as amagnetic disk or a flash memory. The auxiliary memory stores thereinvarious programs for operating the processor 72. The programs stored inthe auxiliary memory are loaded on the main memory and executed by theprocessor 72.

The digital-to-analog converter 77 converts a digital transmissionsignal output from the processor 72 into an analog transmission signal,and outputs the converted transmission signal to the multiplier 78. Themultiplier 78 multiplies the transmission signal converted by thedigital-to-analog converter 77 by the clock signal output from theoscillator 76, to thereby convert the frequency of the transmissionsignal from the baseband to the high-frequency band. Then, themultiplier 78 outputs the transmission signal subjected to the frequencyconversion to the amplifier 79. The amplifier 79 amplifies the signaloutput from the multiplier 78, and outputs the amplified transmissionsignal to outside via the antenna 80.

The oscillator 76 generates a clock signal at a predetermined frequency(an alternating-current signal in the form of a continuous wave). Then,the oscillator 76 outputs the generated clock signal to the multiplier74 and the multiplier 78.

When the wireless communication device 70 functions as the base station20 illustrated in FIG. 4, the antennas 216, 226, 235, and 245illustrated in FIG. 4 are implemented by, for example, the antenna 80.Furthermore, the wireless processing units 215, 225, 234, and 244illustrated in FIG. 4 are implemented by, for example, theanalog-to-digital converter 73, the multiplier 74, the amplifier 75, theoscillator 76, the digital-to-analog converter 77, the multiplier 78,and the amplifier 79. Moreover, the other components illustrated in FIG.4 are implemented by, for example, the processor 72 and the memory 71.

When the wireless communication device 70 functions as the terminal 30illustrated in FIG. 5, the antenna 300 illustrated in FIG. 5 isimplemented by, for example, the antenna 80. Furthermore, the wirelessprocessing units 311, 321, 331, and 341 illustrated in FIG. 5 areimplemented by, for example, the analog-to-digital converter 73, themultiplier 74, the amplifier 75, the oscillator 76, thedigital-to-analog converter 77, the multiplier 78, and the amplifier 79.Moreover, the other components illustrated in FIG. 5 are implemented by,for example, the processor 72 and the memory 71.

[Others]

In the above-described embodiments, each of the UL grants includes theoffset; however, as another example, the offset may be included in thepermission signal. In this case, in the permission signal, the offset tobe used by the terminal 30 is stored in association with theidentification information of the terminal 30 serving as a destinationof each of the UL grants that are transmitted before transmission of thepermission signal.

Furthermore, in the above-described embodiments, the UL grant includesthe identification information having the same value as theidentification information included in the permission signal that isused as a reference when the terminal 30 performs the UL transmission inresponse to the UL grant. However, the disclosed technology is notlimited to this example. For example, when each of the terminals 30receives the permission signal from only the single base station 20, itis possible not to include, in the UL grant, the identificationinformation having the same value as the identification informationincluded in the permission signal.

Incidentally, the components illustrated in the above-describedembodiments are distributed by each function depending on the mainprocessing contents, in order to facilitate the understanding of thedevices. Therefore, the disclosed technology is not limited by how thecomponents are distributed or by the names of the components. Thecomponents of the devices illustrated in the above-described embodimentsmay be distributed into the increased number of components, or any oneof the components may be distributed to perform the increased number ofprocesses, depending on the processing contents. Furthermore, each ofthe processes may be implemented as a process executed by software, ormay be implemented by dedicated hardware, such as an ApplicationSpecific Integrated Circuit (ASIC).

According to one aspect of the present application, it is possible tosuppress a reduction in the throughput in the uplink.

All examples and conditional language provided herein are intended forthe pedagogical purposes of aiding the reader in understanding theinvention and the concepts contributed by the inventors to further theart, and are not to be construed as limitations to such specificallyrecited examples and conditions, nor does the organization of suchexamples in the specification relate to a showing of the superiority andinferiority of the invention. Although one or more embodiments of thepresent invention have been described in detail, it should be understoodthat the various changes, substitutions, and alterations could be madehereto without departing from the spirit and scope of the invention.

What is claimed is:
 1. A base station that performs wirelesscommunication with a terminal by using a dedicated band dedicated to awireless communication system including the base station and theterminal and a shared band shared with other systems, the base stationcomprising: a transmitter configured to transmit, to the terminal usingthe dedicated band, a control signal including first information andsecond information, the first information indicating an uplink resourcein the shared band to be used for data transmission by the terminal, thesecond information indicating a period to wait for a permission signalindicating the data transmission can be performed using the uplinkresource; and a controller configured to determine whether the sharedband is idle or busy, wherein the transmitter transmits, to the terminalvia physical downlink channel, the permission signal transmitted usingthe shared band with different timing from the control signal, thepermission signal for permitting transmission in the shared band whenthe controller determines that the shared band is idle, and the controlsignal and/or the permission signal includes an offset indicating a timefrom receiving the permission signal to a start of transmission of datafrom the terminal to the base station with reference to the permissionsignal transmitted from the transmitter.
 2. The base station accordingto claim 1, wherein the permission signal includes identificationinformation for identifying each of permission signals in the permissionsignals, and the control signal includes same identification informationas the identification information included in the permission signal thatis used as a reference of the offset by the terminal serving as adestination of the control signal.
 3. The base station according toclaim 2, wherein the identification information includes base stationidentification information for identifying the base station.
 4. The basestation according to claim 1, wherein the offset is specified in unitsof a subframe in Long Term Evolution (LTE).
 5. A terminal that performswireless communication with a base station by using a dedicated banddedicated to a wireless communication system including the base stationand the terminal and a shared band shared with other systems, theterminal comprising: a receiver configured to receive using thededicated band, a control signal including first information and secondinformation, the first information indicating an uplink resource in theshared band to be used for data transmission by the terminal, the secondinformation indicating a period to wait for a permission signalindicating the data transmission can be performed using the uplinkresource, and to receive the permission signal for permittingtransmission in the shared band transmitted via physical downlinkchannel from the base station with different timing from the controlsignal; and a transmitter configured to transmit to the base stationusing the uplink resource in the shared band specified by the controlsignal, wherein the control signal and/or the permission signal includesan offset indicating a time from receiving the permission signal to astart of transmission of data to the base station with reference to thepermission signal transmitted from the base station, and the transmittertransmits data to the base station by using the uplink resource in theshared band specified by the control signal after a lapse of the timeindicated by the offset since reception of the permission signal by thereceiver.
 6. The terminal according to claim 5, wherein each of thepermission signal and the control signal includes identificationinformation, and the transmitter transmits data to the base stationafter a lapse of the time indicated by the offset since reception of thepermission signal including same identification information asidentification information included in the control signal transmitted tothe terminal.
 7. The terminal according to claim 6, wherein theidentification information includes base station identificationinformation for identifying the base station.
 8. The terminal accordingto claim 5, wherein the transmitter cancels transmission of data to thebase station when the permission signal is not received until the periodindicated by the second information included in the control signaltransmitted to the terminal.
 9. The terminal according to claim 5,wherein the offset is specified in units of a subframe in LTE.
 10. Awireless communication system comprising: a base station; and aterminal, wherein the base station and the terminal perform wirelesscommunication with each other by using a dedicated band dedicated to thewireless communication system and a shared band shared with othersystems, the base station includes: a first transmitter configured totransmit, to the terminal using the dedicated band, a control signalincluding first information and second information, the firstinformation indicating an uplink resource in the shared band to be usedfor data transmission by the terminal, the second information indicatinga period to wait for a permission signal indicating the datatransmission can be performed using the uplink resource; and acontroller configured to determine whether the shared band is idle orbusy, wherein the first transmitter transmits, to the terminal viaphysical downlink channel, the permission signal transmitted using theshared band with different timing from the control signal, thepermission signal for permitting transmission in the shared band whenthe controller determines that the shared band is idle, and the controlsignal includes an offset indicating a time from receiving thepermission signal to a start of transmission of data from the terminalto the base station with reference to the permission signal transmittedfrom the first transmitter, the terminal includes: a receiver configuredto receive using the dedicated band, the control signal and receiveusing the shared band, the permission signal; a second transmitterconfigured to transmit data to the base station using the uplinkresource in the shared band specified by the control signal after alapse of the time indicated by the offset since reception of thepermission signal by the receiver.